Large Excavations in the US Lee Petersen, CNA Consulting Engineers Presented by Chang Kee Jung, SUNY...
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Transcript of Large Excavations in the US Lee Petersen, CNA Consulting Engineers Presented by Chang Kee Jung, SUNY...
Large Excavations in the US
Lee Petersen, CNA Consulting Engineers
Presented by
Chang Kee Jung, SUNY Stony Brook
NNN05 Conference
April 2005
Topics
• DUSEL sites
• Site characteristics important for large excavations
• Rock engineering
• Relative importance of site characteristics
• Megaton detector feasibility
April 2005
DUSEL Site Locales
Icicle Creek
Homestake
Henderson
Soudan
Kimballton
SanJacinto
SNO
WIPP
April 2005
Solicitation 2 Sites
• Cascades-Icicle Creek, WA– Greenfield escarpment site & nearby railroad tunnel
• Henderson Mine, Empire, CO– Operating molybdenum mine since mid 1970s
• Homestake Mine, Lead, SD– Former operating gold mine
• Kimballton Mine, Giles Co., VA– Limestone mine & adjacent subsurface
April 2005
Solicitation 2 Sites
• San Jacinto, CA– Greenfield escarpment site
• Soudan Mine, Soudan, MN– Operating lab at former iron mine, expansion into
adjacent subsurface
• SNOLAB, Sudbury, Ontario– Operating lab in operating nickel mine
• WIPP, Carlsbad, NM– Operating lab in operating low-level waste facility
April 2005
Characteristics for Large Excavations
• What site characteristics are important for large excavations?– Depth / shielding capacity
– Rock type / rock chemistry
– Rock quality / In situ stress
– Access / rock removal
• Will review each characteristic for each site
• All comments that follow are for large excavations, not DUSEL in general
April 2005
Depth / Shielding Capacity
DUSEL Site Depth / Shielding Capacity
Cascade Adequate
Henderson mine Adequate
Homestake mine Adequate
Kimballton Adequate
San Jacinto Adequate
Soudan Adequate
SNOLAB Adequate
WIPP Adequate
April 2005
Rock Type / Rock Chemistry
DUSEL Site Rock type / chemistryCascade Igneous, insoluble
Henderson mine Igneous, insoluble
Homestake mine Igneous/metamorphic, insoluble
Kimballton Sedimentary, insoluble
San Jacinto Igneous/metasediments, insoluble
Soudan Igneous/metamorphic, insoluble
SNOLAB Igneous/metamorphic, insoluble
WIPP Sedimentary, soluble
April 2005
Rock Quality / In situ Stress
DUSEL Site Rock quality / In situ StressCascade Nearby railroad tunnel
Henderson mine Existing info & nearby mine excavations
Homestake mine Existing info & nearby mine excavations
Kimballton Existing info & nearby mine excavations
San Jacinto Some tunneling nearby
Soudan Existing info & existing lab caverns (different rock)
SNOLAB Existing info & existing lab cavern
WIPP Existing info & existing excavations
No site has sufficient experience to be surethat a megaton detector is feasible!
Summary of available information about site rock quality.
April 2005
Rock Engineering 101
• Rock “material” — strong, stiff, brittle– Weak rock > Strong concrete
– Strong in compression, weak in tension
– Postpeak strength is low unless confined
• Rock “mass” — behavior controlled by discontinuities– Rock mass strength is 1/2 to 1/10 of rock material
strength
• Discontinuities give rock masses scale effects
April 2005
Rock Engineering 101
• Massive rock– Rock masses with few
discontinuities, or– Excavation dimension
< discontinuity spacing
April 2005
Rock Engineering 101
• Jointed or “blocky” rock– Rock masses with
moderate number of discontinuities
– Excavation dimension > discontinuity spacing
April 2005
Rock Engineering 101
• Heavily jointed rock– Rock masses with a
large number of discontinuities
– Excavation dimension >> discontinuity spacing
April 2005
Rock Engineering 101
• Rock stresses in situ– Vertical stress weight of overlying rock
– ~27 KPa / m 35.7 MPa at 1300 m
– Horizontal stress controlled by tectonic forces (builds stresses) & creep (relaxes stresses)
– At depth, v h unless there are active tectonic forces
April 2005
Major Rock Features
• Examples– Geologic contacts
– Joint swarms
– Shears and faults
• Effects– Reduced rock quality
– Reduced strength
– Locus for rockburst / seismic activity
April 2005
Numerical Modeling
• Rock engineering equivalent of bridge or building structural analysis
• Develop understanding of the critical physical parameters– Rock characteristics– Rock stresses– Cavern shape– Rock support & reinforcement
• Common types– Continuum– Discontinuum
April 2005
Simple example
• Continuum model FLAC 2D• 60 x 60 x 180 meters (length
not modeled)• Curved roof & straight walls• Depth 1300 meters• Stresses depth• Example rock properties• Sequential excavation• Rock reinforcement• Model permits rock failure
April 2005
Rock Mass Characterization
• Stages– Choose the best site– Find best location at the chosen site– Prove rock conditions at chosen location
• Volume of rock necessary• Technical objectives
– Provide design basis– Choose proper design and construction techniques– Reduce risk of differing site conditions – Basis for cost estimating– Basis for defining baseline, i.e. contractor bidding
April 2005
Access / Rock Removal
DUSEL Site Access / Rock RemovalCascade Horizontal access & nearby railroad tunnel
Henderson mine 10-mile ore conveyor
Homestake mine Existing shaft ore handling equipment
Kimballton Inclined tunnel to surface
San Jacinto Horizontal access
Soudan Shaft
SNOLAB Shaft & underground use
WIPP Shaft
April 2005
Conclusions about important features
• Depth / shielding capacity– All sites appear adequate
• Rock type / rock chemistry– All sites appear adequate, but salt at WIPP may be
problematic (due to creep & solubility)
• Rock quality / In situ stress– All sites are potentially suitable, but none are guaranteed
feasible
• Access / rock removal– All sites are potentially suitable, but horizontal access is
beneficial
April 2005
What is MOST important?
• Rock type / rock chemistry– Creep & solubility are the principal issues
• Rock quality / In situ stress– Commonly influences costs by a factor of 2 to 4, could
make a site unfeasible
• Access / rock removal– Can influence costs significantly, but is very site
dependent
April 2005
Rock Engineering 101
• What are the implications for large cavern construction?– Find a site with excellent rock
– Characterizing the rock mass is JOB ONE
– Avoid tectonic zones & characterize in situ stresses
– Select size, shape & orientation to minimize rock support, stress concentrations, etc.
• Soudan 2 & MINOS caverns
April 2005
Cost & Risk vs. Site InvestigationP
roje
ct C
ost
Ran
ge
Increased Site Investigation $
Lower Bound of Project Cost
Upper Bound of Project Cost
ActualCost
April 2005
Concluding Remarks
• Is a megadetector feasible? Qualified yes
• What are the qualifications?– Rock conditions & depth
• Best location at the best site, not too deep
– Enlightened funding agencies• Understand & manage the risks, cost uncertainties
– Site factors• Rock removal, competing demands for resources
– Contractor• Chosen on cost & qualifications